Specific class of intrapartum antibiotics relates to maturation of the infant gut microbiota: a prospective cohort study.

OBJECTIVE: To evaluate the potential impact of intrapartum antibiotics, and their specific classes, on the infant gut microbiota in the first year of life. DESIGN: Prospective study of infants in the New Hampshire Birth Cohort Study (NHBCS). SETTINGS: Rural New Hampshire, USA. POPULATION OR SAMPLE: Two hundred and sixty-six full-term infants from the NHBCS. METHODS: Intrapartum antibiotic use during labour and delivery was abstracted from medical records. Faecal samples collected at 6 weeks and 1 year of age were characterised by 16S rRNA sequencing, and metagenomics analysis in a subset of samples. EXPOSURES: Maternal exposure to antibiotics during labour and delivery. MAIN OUTCOME MEASURE: Taxonomic and functional profiles of faecal samples. RESULTS: Infant exposure to intrapartum antibiotics, particularly to two or more antibiotic classes, was independently associated with lower microbial diversity scores as well as a unique bacterial community at 6 weeks (GUnifrac, P = 0.02). At 1 year, infants in the penicillin-only group had significantly lower α diversity scores than infants not exposed to intrapartum antibiotics. Within the first year of life, intrapartum exposure to penicillins was related to a significantly lower increase in several taxa including Bacteroides, use of cephalosporins was associated with a significantly lower rise over time in Bifidobacterium and infants in the multi-class group experienced a significantly higher increase in Veillonella dispar. CONCLUSIONS: Our findings suggest that intrapartum antibiotics alter the developmental trajectory of the infant gut microbiome, and specific antibiotic types may impact community composition, diversity and keystone immune training taxa. TWEETABLE ABSTRACT: Class of intrapartum antibiotics administered during delivery relates to maturation of infant gut microbiota.

Serial analysis of the gut and respiratory microbiome in cystic fibrosis in infancy: interaction between intestinal and respiratory tracts and impact of nutritional exposures.

UNLABELLED: Pulmonary damage caused by chronic colonization of the cystic fibrosis (CF) lung by microbial communities is the proximal cause of respiratory failure. While there has been an effort to document the microbiome of the CF lung in pediatric and adult patients, little is known regarding the developing microflora in infants. We examined the respiratory and intestinal microbiota development in infants with CF from birth to 21 months. Distinct genera dominated in the gut compared to those in the respiratory tract, yet some bacteria overlapped, demonstrating a core microbiota dominated by Veillonella and Streptococcus. Bacterial diversity increased significantly over time, with evidence of more rapidly acquired diversity in the respiratory tract. There was a high degree of concordance between the bacteria that were increasing or decreasing over time in both compartments; in particular, a significant proportion (14/16 genera) increasing in the gut were also increasing in the respiratory tract. For 7 genera, gut colonization presages their appearance in the respiratory tract. Clustering analysis of respiratory samples indicated profiles of bacteria associated with breast-feeding, and for gut samples, introduction of solid foods even after adjustment for the time at which the sample was collected. Furthermore, changes in diet also result in altered respiratory microflora, suggesting a link between nutrition and development of microbial communities in the respiratory tract. Our findings suggest that nutritional factors and gut colonization patterns are determinants of the microbial development of respiratory tract microbiota in infants with CF and present opportunities for early intervention in CF with altered dietary or probiotic strategies. IMPORTANCE: While efforts have been focused on assessing the microbiome of pediatric and adult cystic fibrosis (CF) patients to understand how chronic colonization by these microbes contributes to pulmonary damage, little is known regarding the earliest development of respiratory and gut microflora in infants with CF. Our findings suggest that colonization of the respiratory tract by microbes is presaged by colonization of the gut and demonstrated a role of nutrition in development of the respiratory microflora. Thus, targeted dietary or probiotic strategies may be an effective means to change the course of the colonization of the CF lung and thereby improve patient outcomes.

Prevalence of streptococci and increased polymicrobial diversity associated with cystic fibrosis patient stability.

Diverse microbial communities chronically colonize the lungs of cystic fibrosis patients. Pyrosequencing of amplicons for hypervariable regions in the 16S rRNA gene generated taxonomic profiles of bacterial communities for sputum genomic DNA samples from 22 patients during a state of clinical stability (outpatients) and 13 patients during acute exacerbation (inpatients). We employed quantitative PCR (qPCR) to confirm the detection of Pseudomonas aeruginosa and Streptococcus by the pyrosequencing data and human oral microbe identification microarray (HOMIM) analysis to determine the species of the streptococci identified by pyrosequencing. We show that outpatient sputum samples have significantly higher bacterial diversity than inpatients, but maintenance treatment with tobramycin did not impact overall diversity. Contrary to the current dogma in the field that Pseudomonas aeruginosa is the dominant organism in the majority of cystic fibrosis patients, Pseudomonas constituted the predominant genera in only half the patient samples analyzed and reported here. The increased fractional representation of Streptococcus in the outpatient cohort relative to the inpatient cohort was the strongest predictor of clinically stable lung disease. The most prevalent streptococci included species typically associated with the oral cavity (Streptococcus salivarius and Streptococcus parasanguis) and the Streptococcus milleri group species. These species of Streptococcus may play an important role in increasing the diversity of the cystic fibrosis lung environment and promoting patient stability.

Acinetobacter, Aeromonas and Trichococcus populations dominate the microbial community within urban sewer infrastructure.

We evaluated the population structure and temporal dynamics of the dominant community members within sewage influent from two wastewater treatment plants (WWTPs) in Milwaukee, WI. We generated > 1.1 M bacterial pyrotag sequences from the V6 hypervariable region of 16S rRNA genes from 38 influent samples and two samples taken upstream in the sanitary sewer system. Only a small fraction of pyrotags from influent samples (∼ 15%) matched sequences from human faecal samples. The faecal components of the sewage samples included enriched pyrotag populations from Lactococcus and Enterobacteriaceae relative to their fractional representation in human faecal samples. In contrast to the large number of distinct pyrotags that represent faecal bacteria such as Lachnospiraceae and Bacteroides, only one or two unique V6 sequences represented Acinetobacter, Aeromonas and Trichococcus, which collectively account for nearly 35% of the total sewage community. Two dominant Acinetobacter V6 pyrotags (designated Acineto tag 1 and Acineto tag 2) fluctuated inversely with a seasonal pattern over a 3-year period, suggesting two distinct Acinetobacter populations respond differently to ecological forcings in the system. A single nucleotide change in the V6 pyrotags accounted for the difference in these populations and corresponded to two phylogenetically distinct clades based on full-length sequences. Analysis of wavelet functions, derived from a mathematical model of temporal fluctuations, demonstrated that other abundant sewer associated populations including Trichococcus and Aeromonas had temporal patterns similar to either Acineto tag 1 or Acineto tag 2. Populations with related temporal fluctuations were found to significantly correlate with the same WWTP variables (5-day BOD, flow, ammonia, total phosphorous and suspended solids). These findings illustrate that small differences in V6 sequences can represent phylogenetically and ecologically distinct taxa. This work provides insight into microbial community composition and dynamics within the defined environment of urban sewer infrastructure.

Three retrotransposon families in the genome of Giardia lamblia: two telomeric, one dead.

Transposable elements inhabiting eukaryotic genomes are generally regarded either as selfish DNA, which is selectively neutral to the host organism, or as parasitic DNA, deleterious to the host. Thus far, the only agreed-upon example of beneficial eukaryotic transposons is provided by Drosophila telomere-associated retrotransposons, which transpose directly to the chromosome ends and thereby protect them from degradation. This article reports the transposon content of the genome of the protozoan Giardia lamblia, one of the earliest-branching eukaryotes. A total of three non-long terminal repeat retrotransposon families have been identified, two of which are located at the ends of chromosomes, and the third one contains exclusively dead copies with multiple internal deletions, nucleotide substitutions, and frame shifts. No other reverse transcriptase- or transposase-related sequences were found. Thus, the entire genome of this protozoan, which is not known to reproduce sexually, contains only retrotransposons that are either confined to telomeric regions and possibly beneficial, or inactivated and completely nonfunctional.

Giardia lamblia expresses a proteobacterial-like DnaK homolog.

We identified a novel gene encoding molecular chaperone HSP70 in the amitochondriate parasite Giardia lamblia. The predicted protein is similar to bacterial DnaK and mitochondrial HSP70s. The gene is transcribed and translated at a constant level during trophozoite growth and encystation. Alignment of the sequence with a data set of cytosolic, endoplasmic reticulum (ER), mitochondrial, and DnaK HSP70 homologs indicated that the sequence was extremely divergent and contained insertions unique to giardial HSP70s. Phylogenetic analyses demonstrated that this sequence was distinct from the cytosolic and ER forms and was most similar to proteobacterial and mitochondrial DnaKs. However, a specific relationship with the alpha proteobacterial and mitochondrial sequences was not strongly supported by phylogenetic analyses of this data set, in contrast to similar analyses of cpn60. These data neither confirm nor reject the possibility that this gene is a relic of secondary mitochondrial loss; they leave open the possibility that it was acquired in a separate endosymbiotic event.

The Giardia genome project database.

The Giardia genome project database provides an online resource for Giardia lamblia (WB strain, clone C6) genome sequence information. The database includes edited single-pass reads, the results of BLASTX searches, and details of progress towards sequencing the entire 12 million-bp Giardia genome. Pre-sorted BLASTX results can be retrieved based on keyword searches and BLAST searches of the high throughput Giardia data can be initiated from the web site or through NCBI. Descriptions of the genomic DNA libraries, project protocols and summary statistics are also available. Although the Giardia genome project is ongoing, new sequences are made available on a bi-monthly basis to ensure that researchers have access to information that may assist them in the search for genes and their biological function. The current URL of the Giardia genome project database is www.mbl.edu/Giardia.

Cloning and sequencing of an acetyl-CoA synthetase (ADP-forming) gene from the amitochondriate protist, Giardia lamblia.

A Giardia lamblia gene, Glacs, was cloned, sequenced and expressed in Escheria Coli. This gene codes for a 726 residue long acetyl-CoA synthetase (ADP-forming). This enzyme is responsible for the formation of acetate, a metabolic endproduct of G. lamblia. It is known from only two Type I amitochondriate eukaryotes, G. lamblia and Entamoeba histolytica and from the archaebacterium, Pyrococcus furiosus. With Glacs as query, homologous unidentified open reading frames were detected in the complete genomes of only a few archaebacteria and eubacteria. These form a new protein family present in all three domains of life, which probably plays a central role in the acyl-CoA metabolism but is of restricted taxonomic distribution.

Primary structure and phylogenetic relationships of a malate dehydrogenase gene from Giardia lamblia.

The lactate and malate dehydrogenases comprise a complex protein superfamily with multiple enzyme homologues found in eubacteria, archaebacteria, and eukaryotes. In this study we describe the sequence and phylogenetic relationships of a malate dehydrogenase (MDH) gene from the amitochondriate diplomonad protist, Giardia lamblia. Parsimony, distance, and maximum-likelihood analyses of the MDH protein family solidly position G. lamblia MDH within a eukaryote cytosolic MDH clade, to the exclusion of chloroplast, mitochondrial, and peroxisomal homologues. Furthermore, G. lamblia MDH is specifically related to a homologue from Trichomonas vaginalis. This MDH topology, together with published phylogenetic analyses of beta-tubulin, chaperonin 60, valyl-tRNA synthetase, and EF-1alpha, suggests a sister-group relationship between diplomonads and parabasalids. Since these amitochondriate lineages contain genes encoding proteins which are characteristic of mitochondria and alpha-proteobacteria, their shared ancestry suggests that mitochondrial properties were lost in the common ancestor of both groups.

Sequence and phylogenetic position of a class II aldolase gene in the amitochondriate protist, Giardia lamblia.

A Giardia lamblia gene, Glfba, was cloned and sequenced. This gene codes for a 324-residue-long putative class II fructose-1, 6-bisphosphate aldolase. The positions of gaps and phylogenetic analysis with maximum likelihood and maximum parsimony methods showed the sequence to be most closely related to the as-yet uncharacterized aldolases of Helicobacter pylori and Aquifex aeolicus and to the group that comprises the Calvin-cycle aldolases of photosynthetic proteobacteria and cyanobacteria. In combination with the known taxonomic and functional distribution of class I and II aldolases, the results indicate that the G. lamblia enzyme is distinct in its evolutionary history from all eukaryotic fructose-1, 6-bisphosphate aldolases studied so far.

Molecular cloning of CYP1A from the estuarine fish Fundulus heteroclitus and phylogenetic analysis of CYP1 genes: update with new sequences.

Since we published a phylogenetic analysis of the CYP1A subfamily in 1995, several additional full-length sequences have been reported, including three members of an entirely new subfamily, CYP1B. Two avian sequences were recently published, so that CYP1A sequence data are now available from three of the five major vertebrate lineages. The two new branches that have been added to the CYP1 family tree significantly add to our understanding of P450 evolution. The inclusion of the CYP1Bs to the phylogenetic analysis allows us to root inferred trees. Addition of the avian CYP1As indicates that the CYP1A1/CYP1A2 duplication present in the mammalian lineage may have occurred after the divergence of birds and mammals. The number of fish species from which full-length coding regions of CYP1A genes have been sequenced has increased from four (trout, plaice, toadfish, and scup) to nine. These include CYP1A sequences from tomcod, butterflyfish, sea bream, sea bass, and the full-length sequence of CYP1A from the killifish Fundulus heteroclitus that is reported here. Phylogenetic analyses incorporating the new fish CYP1A sequences support our original conclusion that the fish CYP1As are monophyletic and indicate that the genes are evolving at very different rates in different species.

Ancestral relationships of the major eukaryotic lineages.

Molecular systematics has revolutionized our understanding of microbial evolution. Phylogenetic frameworks relating all organisms in this biosphere can be inferred from comparisons of slowly evolving molecules such as the small and large subunit ribosomal RNAs. Unlike today's text book standard, the "Five Kingdoms" (plants, animals, fungi, protists and bacteria), molecular studies define three primary lines of descent (Eukaryotes, Eubacteria, and Archaebacteria). Within the Eukaryotes, the "higher" kingdoms (Fungi, Plantae, and Animalia) are joined by at least two novel complex evolutionary assemblages, the "Alveolates" (ciliates, dinoflagellates and apicomplexans) and the "Stramenopiles" (diatoms, oomycetes, labyrinthulids, brown algae and chrysophytes). The separation of these eukaryotic groups (described as the eukaryotic "crown") occurred approximately 10(9) years ago and was preceded by a succession of earlier diverging protist lineages, some as ancient as the separation of the prokaryotic domains. The molecular phylogenies suggest that multiple endosymbiotic events introduced plastids into discrete eukaryotic lineages.

Identification of V3 mutations that can compensate for inactivating mutations in C4 of simian immunodeficiency virus.

A valine to isoleucine substitution at position 322 within variable region 3 (V3) of envelope of simian immunodeficiency virus was previously shown to compensate for an inactivating valine to glycine mutation at position 448 in constant region 4 (C4) (Morrison et al., Virology 195, 167-174, 1993). Cloned DNA fragments with inactivating C4 mutations were combined with complex mixtures of mutant V3 sequences, and full length genomes were transfected into COS-1 cells. By cocultivating transfected cells with CEM x 174 cells, we were able to identify two additional compensatory V3-C4 combinations. Changing 334 proline to leucine compensated for an inactivating 428 asparagine to lysine mutation and changing 324 isoleucine to leucine compensated for an inactivating 448 valine to glycine mutation. The double mutants replicated efficiently in CEM x 174 cells, rhesus monkey peripheral blood mononuclear cells, and the continuously growing rhesus monkey T cell line 221. Surprisingly, the 324 I-->L and 33 P-->L mutations by themselves impaired SIVmac239 wild-type replication in CEM x 174 cells. These results confirm the cooperation between V3 and C4 sequences and they define additional specific residues participating in this cooperation.

Phylogeny of trichomonads inferred from small-subunit rRNA sequences.

Small subunit (16S-like) ribosomal RNA sequences were obtained from representatives of all four families constituting the order Trichomonadida. Comparative sequence analysis revealed that the Trichomonadida are a monophyletic lineage and a deep branch of the eukaryotic tree. Relative to the early divergent eukaryotic assemblages the branching pattern within the Trichomonadida is very shallow. This pattern suggests the Trichomonadida radiated recently, perhaps in conjunction with their animal hosts. From a morphological perspective the Devescovinidae and Calonymphidae are considered more derived than the Monocercomonadidae and Trichomonadidae. Molecular trees inferred by distance, parsimony and likelihood techniques consistently show the Devescovinidae and Calonymphidae are the earliest diverging lineages within the Trichomonadida, however bootstrap values do not strongly support a particular branching order. In an analysis of all known 16S-like ribosomal RNA sequences, the Trichomonadida share most recent common ancestry with unidentified protists from the hindgut of the termite Reticulitermes flavipes. The position of two putative free-living trichomonads in the tree is indicative of derivation from symbionts rather than direct descent from some free-living ancestral trichomonad.

Effects of mutations in constant regions 3 and 4 of envelope of simian immunodeficiency virus.

Twenty-six mutant forms of simian immunodeficiency virus strain mac239 were constructed with changes in constant region 4 (C4) of env. Twenty-four of these had a single amino acid change, one had changes in two amino acids, and one had a deletion of eight amino acids. The effects of these mutations on viral replication, gp160 processing, and binding of env protein to soluble CD4 receptor were analyzed. The C4 region was relatively sensitive to sequence changes since only 11 of the 26 mutants replicated appreciably. Eight of the 15 mutants that were replication incompetent exhibited grossly defective processing of the gp160 env precursor; these mutations likely resulted in global effects on gp160 structure. Six of the replication incompetent mutants exhibited normal or near normal gp160 processing and binding of env protein to sCD4 and thus were probably blocked at some step subsequent to binding of virus to its CD4 receptor. Only one of the C4 mutations, 441W-->R, resulted in greatly decreased binding to sCD4 while retaining normal processing of gp160. The equivalent residue in HIV-1 has similarly been shown previously to be important for binding of HIV-1 to the CD4 receptor. Since a W-->S mutation at position 441 in C4 of SIVmac239 affected both gp160 processing and sCD4 binding, it is not clear whether the 441 tryptophan is actually important for contacting CD4 or for maintaining an appropriate configuration. mutations within a highly conserved GGDPE sequence in C3 of SIVmac239 specifically affected CD4 binding, which is also similar to previous findings with HIV-1. These results demonstrate similar sequence requirements in SIVmac and HIV-1 env for binding C4, but they raise doubts as to whether C4 sequences are directly involved in the binding.

Identification of cytochrome P-450 1A (CYP1A) genes from two teleost fish, toadfish (Opsanus tau) and scup (Stenotomus chrysops), and phylogenetic analysis of CYP1A genes.

Cytochrome P-450-mediated responses to environmental challenges are well known in diverse animal taxa, but the evolution of the complex gene superfamily coding for these enzymes is poorly understood. Here we report a phylogenetic analysis of the cytochrome P-450 1A (CYP1A) genes including two new sequences determined from teleost fish, toadfish (Opsanus tau) and scup (Stenotomus chrysops). Degenerate PCR primers were used to amplify a 1.2 kbp fragment from liver cDNA. The toadfish PCR product was used as a probe to identify a full-length CYP1A clone from a toadfish liver cDNA library. The entire coding region of the scup CYP1A was obtained by rapid amplification of cDNA ends (RACE) using specific primers based on the sequence of the partial PCR product. The predicted protein sequences for toadfish and scup CYP1A shared 78% and 83% amino acid identity with rainbow trout CYP1A1 respectively. Amino acid identity with mammalian CYP1A proteins ranged from 51 to 60% for 505 aligned positions. Phylogenetic analysis of four teleost fish CYP1A genes (trout, toadfish, scup and plaice) and 12 mammalian CYP1A genes suggests a monophyletic origin of the teleost genes, with the trout gene being most divergent, and indicates three distinct groupings: mammalian 1A1, mammalian 1A2, and fish 1A. This supports the idea that the gene duplication event which gave rise to CYP1A1 and CYP1A2 occurred after the divergence of the lines leading to mammals and fish. These results establish a molecular phylogeny within the CYP1A subfamily, the first such detailed phylogenetic analysis within a cytochrome P-450 family.

SIVmac expressing hybrid envelope proteins containing HIV-1 V3 and/or C4 sequences is not competent for replication.

The V3- and C4-coding regions in the envelope gene of the infectious, pathogenic SIVmac239 clone were replaced by the corresponding HIV-1 sequences. Viral particles were obtained after transfection of COS-1 cells. Chimeric SIVmac constructs were not replication competent in the human T cell lines CEMx174, AA2, H9, and MT-4 or in primary cultures of rhesus monkey peripheral blood mononuclear cells. The lack of infectivity of the hybrid constructs was associated with inefficient proteolytic processing of the gp160env precursor. Unlike the modular nature of some proteins, gp120 appears to be a highly ordered molecule whose function is dependent on the integration of many discontinuous, interactive regions.